English

Fine-grained Generalization Analysis of Vector-valued Learning

Machine Learning 2021-04-30 v1 Artificial Intelligence

Abstract

Many fundamental machine learning tasks can be formulated as a problem of learning with vector-valued functions, where we learn multiple scalar-valued functions together. Although there is some generalization analysis on different specific algorithms under the empirical risk minimization principle, a unifying analysis of vector-valued learning under a regularization framework is still lacking. In this paper, we initiate the generalization analysis of regularized vector-valued learning algorithms by presenting bounds with a mild dependency on the output dimension and a fast rate on the sample size. Our discussions relax the existing assumptions on the restrictive constraint of hypothesis spaces, smoothness of loss functions and low-noise condition. To understand the interaction between optimization and learning, we further use our results to derive the first generalization bounds for stochastic gradient descent with vector-valued functions. We apply our general results to multi-class classification and multi-label classification, which yield the first bounds with a logarithmic dependency on the output dimension for extreme multi-label classification with the Frobenius regularization. As a byproduct, we derive a Rademacher complexity bound for loss function classes defined in terms of a general strongly convex function.

Keywords

Cite

@article{arxiv.2104.14173,
  title  = {Fine-grained Generalization Analysis of Vector-valued Learning},
  author = {Liang Wu and Antoine Ledent and Yunwen Lei and Marius Kloft},
  journal= {arXiv preprint arXiv:2104.14173},
  year   = {2021}
}

Comments

To appear in AAAI 2021

R2 v1 2026-06-24T01:37:25.479Z